Researchers discover evidence that lead exposure in mothers can affect future generation

IMAGE: This is Dr. Douglas Ruden, professor in the Department of Obstetrics & Gynecology and the Institute of Environmental Health Sciences, director of epigenomics, and program leader in the Center for...
view more

Credit: Wayne State University

DETROIT - A team of researchers at Wayne State University have discovered that mothers with high levels of lead in their blood not only affect the fetal cells of their unborn children, but also their grandchildren. Their study, Multigenerational epigenetic inheritance in humans: DNA methylation changes associated with maternal exposure to lead can be transmitted to the grandchildren, was published online this week in Scientific Reports.

It's a known fact that babies in the womb can be affected by low levels of lead exposure. If a pregnant woman is exposed to lead, the lead passes through the placenta into the baby's developing bones and other organs. Pregnant women with a past exposure to lead can also affect the unborn child's brain, causing developmental problems later in life. Previous research studies have suggested that exposure to heavy metal toxicants can influence a person's global DNA methylation profile.

In the recent Wayne State study led by Douglas Ruden, Ph.D., professor in the Department of Obstetrics & Gynecology and the Institute of Environmental Health Sciences, director of epigenomics, and program leader in the Center for Urban Responses to Environmental Stressors, he and his research team revealed that lead exposure can cause specific changes in DNA methylation, which can be detected in dried blood spots beyond one generation. The neonatal blood spots from both the mothers and children in this study were obtained from the Michigan Neonatal Biobank, a unique resource that has most of the neonatal dried blood spots from children born in Michigan since 1984.

According to Ruden, epigenetic effects of environmental exposures beyond one generation have not yet been demonstrated in humans prior to this study. He and his team tested the hypothesis that human fetal germ cell exposure to environmental toxins causes epigenetic changes in the newborn blood from a grandchild of an exposed pregnant woman.

"Our results suggest that lead exposure during pregnancy affects the DNA methylation status of the fetal germ cells, which leads to altered DNA methylation in grandchildren's neonatal dried blood spots," said Ruden. "This is the first demonstration that an environmental exposure in pregnant mothers can have an epigenetic effect on the DNA methylation pattern in the grandchildren."

The research team stated that this novel, two-generational study design might be able to identify the genes that may serve as possible candidate biomarkers for future transgenerational risk assessment studies.

"Our pilot study provides indirect evidence that lead exposure in women during childbirth can affect the locus-specific DNA methylation status of grandchildren," said Ruden. "However, the altered DNA methylation profiles of the grandchildren's blood are apparently normalized during postnatal development. Also, fetal germline exposure to lead apparently has different epigenetic consequences than acute childhood exposure."

###

This research was supported by the National Institute of Environmental Health Sciences of the National Institutes of Health (R01 ES012933 and R21 ES021893) to Dr. Ruden, the WSU-NIEHS Center (P30 ES020957), and a Michigan Bloodspot Environmental Epidemiology Project (BLEEP) pilot grant from the Michigan University Research Corridor to Dr. Ruden.

Wayne State University is a premier urban research institution offering more than 400 academic programs through 13 schools and colleges to nearly 32,000 students. Its School of Medicine is the largest single-campus medical school in the nation with more than 1,200 medical students. In addition to undergraduate medical education, the school offers master's degree, Ph.D. and M.D.-Ph.D. programs in 14 areas of basic science to about 400 students annually.

Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.